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Powerful, Onset Inhibition in the Ventral Nucleus of the Lateral Lemniscus David A. X. Nayagam, Janine C. Clarey and Antonio G. Paolini J Neurophysiol 94:1651-1654, 2005. First published 7 April 2005; doi:10.1152/jn.00167.2005 You might find this additional info useful... This article cites 23 articles, 11 of which can be accessed free at: http://jn.physiology.org/content/94/2/1651.full.html#ref-list-1 This article has been cited by 8 other HighWire hosted articles, the first 5 are: Going native: voltage-gated potassium channels controlling neuronal excitability Jamie Johnston, Ian D. Forsythe and Conny Kopp-Scheinpflug J Physiol, September, 1 2010; 588 (17): 3187-3200. [Abstract] [Full Text] [PDF] Inferior Colliculus Responses to Multichannel Microstimulation of the Ventral Cochlear Nucleus: Implications for Auditory Brain Stem Implants Mohit N. Shivdasani, Stefan J. Mauger, Graeme D. Rathbone and Antonio G. Paolini J Neurophysiol, January, 1 2008; 99 (1): 1-13. [Abstract] [Full Text] [PDF] Rethinking Tuning: In Vivo Whole-Cell Recordings of the Inferior Colliculus in Awake Bats Ruili Xie, Joshua X. Gittelman and George D. Pollak J. Neurosci., August, 29 2007; 27 (35): 9469-9481. [Abstract] [Full Text] [PDF] First-spike latency information in single neurons increases when referenced to population onset Steven M. Chase and Eric D. Young PNAS, March, 20 2007; 104 (12): 5175-5180. [Abstract] [Full Text] [PDF] Updated information and services including high resolution figures, can be found at: http://jn.physiology.org/content/94/2/1651.full.html Additional material and information about Journal of Neurophysiology can be found at: http://www.the-aps.org/publications/jn This infomation is current as of March 4, 2011. Journal of Neurophysiology publishes original articles on the function of the nervous system. It is published 12 times a year (monthly) by the American Physiological Society, 9650 Rockville Pike, Bethesda MD 20814-3991. Copyright © 2005 by the American Physiological Society. ISSN: 0022-3077, ESSN: 1522-1598. Visit our website at http://www.the-aps.org/. Downloaded from jn.physiology.org on March 4, 2011 Glycinergic Inhibition Creates a Form of Auditory Spectral Integration in Nuclei of the Lateral Lemniscus Diana Coomes Peterson, Kiran Nataraj and Jeffrey Wenstrup J Neurophysiol, UNKNOWN, 2009; 102 (2): 1004-1016. [Abstract] [Full Text] [PDF] J Neurophysiol 94: 1651–1654, 2005. First published April 7, 2005; doi:10.1152/jn.00167.2005. Report Powerful, Onset Inhibition in the Ventral Nucleus of the Lateral Lemniscus David A. X. Nayagam,1,2 Janine C. Clarey,1 and Antonio G. Paolini3 1 The Bionic Ear Institute, East Melbourne, Victoria; 2Department of Otolaryngology, The University of Melbourne, East Melbourne, Victoria; and 3School of Psychological Science, LaTrobe University, Bundoora, Victoria, Australia Submitted 16 February 2005; accepted in final form 1 April 2005 termed onset-ideal (OI). This response pattern is a result of the detection of synchrony in auditory nerve fiber inputs representing a wide range of characteristic frequencies (CFs) (Golding et al. 1995; Oertel et al. 2000). The function of these cells and their projection to the VNLL is unknown, although they seem well suited to encode onsets, transients, and temporal features of complex, periodic stimuli (Oertel and Wickesberg 2002). The role of the VNLL’s projection to the IC (Kelly et al. 1998; Merchán and Berbel 1996), which is inhibitory (Batra and Fitzpatrick 2002; Oertel and Wickesberg 2002) is equally uncertain. We used in vivo intracellular recordings to investigate how VNLL cells utilize this well-timed onset information. METHODS Various lines of evidence indicate that inhibition plays as important a role as excitation in controlling spike timing in auditory nuclei (Brand et al. 2002; Casseday et al. 2000, 1994; Wehr and Zador 2003). One of the major inhibitory pathways within the auditory brain stem originates in the ventral nucleus of the lateral lemniscus (VNLL) (Saintmarie and Baker 1990; Zhao and Wu 2001), a nucleus thought to play a role in temporal pattern processing (Covey and Casseday 1999; Oertel and Wickesberg 2002). This structure is a crucial integration site for a subset of fibers from the lower auditory brain stem en route to the inferior colliculus (IC) (Covey and Casseday 1999; Oertel and Wickesberg 2002; Wu 1999). VNLL neurons receive convergent excitatory input from a variety of cell types within the contralateral cochlear nucleus (CN) (Glendenning et al. 1981; Zhao and Wu 2001), including an exclusive projection from the octopus cell area (OCA) of the contralateral CN (Adams 1997; Schofield and Cant 1997). Octopus cells give rise to thick axons that terminate in large calyx-like synapses, akin to endbulbs of Held in other auditory nuclei (Adams 1997; Schofield and Cant 1997). These characteristics suggest that this pathway provides fast and faithful transmission of timing information (Batra and Fitzpatrick 1999; Zhao and Wu 2001). Octopus cells respond to the onsets of sounds with exquisitely timed responses (Godfrey et al. 1975; Rhode and Smith 1986), Experiments were performed on 26 male Hooded Wistar (pigmented) rats weighing between 250 and 360 g. Animals were anesthetized with intraperitoneal aqueous urethan (20% wt/vol: total dose: 2.6 g/kg; Sigma, Sydney, Australia), and supplementary doses were administered during the experiment if a corneal or paw reflex was observed. Some animals were initially sedated with isoflurane (4 –5% in 2% O2) prior to injection of urethan. The animal’s temperature was maintained at ⬃37.5°C by a thermostatically controlled heating pad. At the end of the recording session, the animal was intra-cardially perfused with 10% formalin. Brains were removed, postfixed in 10% formalin, and sectioned on a freezing sledge microtome (100 m sections). Sections were stained for Nissl substance using thionin, and standard histological procedures were used to reconstruct and verify the location of electrode tracks and recorded units (Paolini et al. 2001). Reconstructed recording depths were referenced to the cortical surface as well as the point at which the electrode broke when it hit the pia underlying the ventral brain stem (Paolini et al. 2001). A dramatic drop in microelectrode impedance indicated this breaking point. All procedures were in accordance with the Royal Victorian Eye and Ear Hospital Animal Research Ethics Committee guidelines (project approval codes 95/037 and 04/104A). Once the animal was deeply anesthetized, it was placed in a stereotaxic frame, and a pinhole craniotomy (area: ⬃4 mm2) was made using stereotaxic coordinates (Paxinos and Watson 1998) and skull suture landmarks as guides. Recording micropipettes were inserted dorsoventrally into the left hemisphere and traversed the cerebral cortex and IC before encountering the lateral lemniscus and its dorsal and ventral nuclei. Intracellular neural responses were recorded using quartz glass micropipettes (1.0 mm OD, 0.7 mm ID, Sutter Instruments, Novato, CA), filled with 1 M potassium acetate and with impedances ranging from 30 to 70 M⍀. The amplified (Axoclamp 2B amplifier, Axon Instruments, Union City, CA) and filtered signal (output bandwidth ⫽ 1 kHz) from the microelectrode was played through a speaker and displayed on a Tektronix 465 storage oscilloscope (Beaverton, OR). Address for reprint requests and other correspondence: A.G. Paolini, School of Psychological Science, La Trobe University, Bundoora, Victoria 3086, Australia (E-mail: a.paolini@latrobe.edu.au). The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. INTRODUCTION www.jn.org 0022-3077/05 $8.00 Copyright © 2005 The American Physiological Society 1651 Downloaded from jn.physiology.org on March 4, 2011 Nayagam, David A. X., Janine C. Clarey, Antonio G. Paolini. Powerful, Onset Inhibition in the Ventral Nucleus of the Lateral Lemniscus. J Neurophysiol 94: 1651–1654, 2005. First published April 7, 2005; doi:10.1152/jn.00167.2005. The function of the ventral nucleus of the lateral lemniscus (VNLL), a secondary processing site within the auditory brain stem, is unclear. It is known to be a major source of inhibition to the inferior colliculus (IC). It is also thought to play a role in coding the temporal aspects of sound, such as onsets and the periodic components of complex stimuli. In vivo intracellular recordings from VNLL neurons (n ⫽ 56) in urethane anesthetized rats revealed the presence of large-amplitude, short-duration, onset inhibition in a subset of neurons (14.3%). This inhibition occurred before the first action potential (AP) elicited by noise or tone bursts, was broadly tuned to tonal frequency and was shown to delay the first AP. Our data suggest it is a result of an intrinsic circuit activated by the octopus cell pathway originating in the contralateral cochlear nucleus; this pathway is known to convey exquisitely timed and broadly tuned onset information. This powerful inhibition within the VNLL appears to control the timing of this structure’s inhibitory output to higher centers, which has important auditory processing outcomes. The circuit also provides a pathway for fast, broadly tuned, onset inhibition to the IC. Report 1652 D.A.X. NAYAGAM, J. C. CLAREY, AND A. G. PAOLINI RESULTS AND DISCUSSION Intracellular recordings from 56 VNLL neurons revealed that a subset (14.3%; 8/56) showed contralaterally evoked inhibitory post synaptic potentials (IPSPs) before the first AP elicited by noise and tones (Fig. 1A). These monaurally driven IPSPs were large amplitude with a mean of 8.0 ⫾ 1.8 (SE) mV and ranged between 3.7 and 19.1 mV. There was no relationship between IPSP amplitude and resting membrane potential (RMP) in these cells (r ⫽ 0.05; P ⬎ 0.05; mean RMP ⫽ ⫺48 ⫾ 4 mV.) In response to noise bursts, the average latency of maximum hyperpolarization was 5.6 ⫾ 0.3 ms (Fig. 1D, white bars), and the AP in these cells occurred with a mean first spike latency (FSL) of 8.5 ⫾ 1.0 ms (Fig. 1D, black bars). The inhibition showed a fast and reliable time course. In two cells that displayed spontaneous IPSPs, of similar magnitude to the stimulus evoked IPSP, it was possible to observe the full inhibitory time course of ⬃8 ms (Fig. 1C). The inhibition was also broadly tuned to tonal frequency (Fig. 1B). J Neurophysiol • VOL FIG. 1. Onset inhibition in ventral nucleus of the lateral lemniscus (VNLL) neurons. A: in vivo intracellular responses recorded from a VNLL neuron to contralaterally presented noise bursts (80 dB RMS; 20 trace overlay, lighter gray) and a characteristic frequency (CF) tone burst (80 dB SPL; single trace, darker gray). Horizontal dashed line indicates the mean resting membrane potential (RMP; ⫺47 ⫾ 4 mV). The arrow indicates membrane hyperpolarization and the horizontal bar indicates stimulus duration. B: single traces to off-CF tone bursts. Horizontal bar indicates time scale from stimulus onset. C: spontaneous inhibitory postsynaptic potentials (IPSPs) were also observed in this cell (black trace) and are compared with the onset component of a single noise response (gray trace). Asterisks indicate truncated action potentials (APs). D: distribution of latencies of first AP (black bars) and maximum hyperpolarization (white bars) for cells with onset inhibition. E: first spike latency (FSL) distribution of VNLL OI neurons. Vertical dashed lines indicate the average of each sample (see text). Bin widths are 0.25 ms. Several questions arise from these observations, including what is the source of this onset inhibition and what is its function? The short and consistent latency of the IPSPs, its prominence at noise or tone onset, and its broad frequency tuning suggest the involvement of the octopus cell pathway. However, this pathway is excitatory (Adams 1997; Oertel and Wickesberg 2002), and therefore we hypothesized that this inhibition resulted from the activation of another VNLL neuron that received octopus cell inputs (Fig. 2a). For this to be the case, there must be a subset of VNLL neurons that respond at short latency and prior to the observed inhibition. Figure 1E shows that such a cell group exists (n ⫽ 10), responding with a mean FSL of 4.6 ⫾ 0.3 ms. Importantly, these cells showed an OI response pattern to contralateral acoustic stimulation (Fig. 2a1), consistent with an octopus cell input. The proposed circuitry is also consistent with the anatomical description of collateral branches from VNLL cells that form local and presumably inhibitory circuits within this structure (Zhao and Wu 2001) (Fig. 2, gray axon). Another possible candidate for the source of this inhibition is the glycinergic principal cell of the MNTB that is known to project to the VNLL (Glendenning et al. 1981). However, the narrow frequency tuning and sus- 94 • AUGUST 2005 • www.jn.org Downloaded from jn.physiology.org on March 4, 2011 The microelectrode was advanced remotely, using a motorized microdrive (MPC-100; Sutter Instruments), in small steps (2 m) once the VNLL was encountered, but occasionally intracellular recordings were made from the IC (n ⫽ 14). Stimuli presented to both ears were 50 ms in duration with 5 ms rise-fall times and a 500 ms repetition interval; the left and right transducer outputs were offset by 200 ms. Responsive neurons were detected using a “search” stimulus of 80 dB noise bursts. Intracellular impalements were signaled by a sudden and stable drop (⬎25 mV) in the DC level and the presence of synaptic or large action potentials (⬎15 mV). Intracellular recordings typically lasted 2 min (maximum: ⬃30 min); however, some recordings lasted for shorter periods, and only responses to noise bursts were obtained. This limitation was due to the difficulty in maintaining an in vivo impalement at recording depths of 5– 8.5 mm from the brain surface. A Maclab 4-s dataacquisition system (AD Instruments, Sydney, Australia) was used to store membrane potential records (traces) at a bandwidth of 20 or 40 kHz. Once impaled, the neuron’s CF and rate-level function at CF were determined. Other data (e.g., binaural response properties) were also sometimes collected as part of a larger study; however, such data are not presented in this report. Acoustic stimuli were synthesized digitally and generated by either Beyer DT48 transducers (Beyerdynamic, Farmingdale, NY) or Tucker-Davis Technologies (TDT, Gainesville, FL) EC1 electrostatic speakers in concert with a TDT ED1 speaker driver. All transducers were controlled by a TDT signal generator (TDT System 2) and coupled to the end of each hollow earbar. The department’s PC based “Neurophysiology Laboratory System” (program by R. E. Millard) was used to control all parameters of acoustic stimulation and data collection. The acoustic system was calibrated using a Brüel and Kjær (B&K) measuring amplifier (type 2606, Brüel & Kjær, Naerum, Denmark). Beyer transducers were calibrated with a B&K 0.5-in condenser microphone, coupled to a small probe tube positioned within the ear bar tube ⬃3 mm from the tympanic membrane. The TDT speakers were calibrated using a 0.25-in B&K condenser microphone inserted into a custom built acoustic coupler designed to simulate the rat’s ear canal at the end of the hollow earbar (designed and built by R. E. Millard). Both these methods allowed acoustic input to be measured in dB sound pressure level (SPL; referenced to 20 Pa). The noise bandwidth generated by TDT EC1 speakers was measured with a Stanford Research Systems dynamic signal analyzer (SR785, Sunnyvale, CA) and found to be spectrally flat at 80 ⫾ 10 dB between 20 Hz and 60 kHz. The Beyer transducers had a nominal bandwidth of 45 Hz to 50 kHz with most of the energy ⬍30 kHz; there was a gradual roll-off between 5–30 kHz of 10 dB/octave. Report POWERFUL, FAST INHIBITION IN THE AUDITORY BRAIN STEM 1653 tained responses of these neurons (Paolini et al. 2001) would suggest that this is unlikely. Excluding OI cells, a comparison of cells with and without (n ⫽ 38) onset inhibition shows that the former group had longer mean FSLs than the latter group (not shown; respectively, 8.5 vs. 7.3 ms). Therefore this inhibition delays the first AP in a subset of VNLL neurons. This conclusion is supported by the data presented in Fig. 2b1; this cell did not exhibit onset inhibition in a small subset of stimulus presentations (black traces) and the presence of inhibition (gray traces) resulted in a longer FSL (means of 6.2 vs. 8.5 ms, respectively). The amplitude and time course of the fast inhibition described in the preceding text is similar to that observed within the MNTB, a structure that also receives calyceal inputs (Awatramani et al. 2004). Awatramani and colleagues (2004) proposed that fast inhibition may control the excitatory drive from a calyx. However, in the VNLL the calyx appears to trigger fast inhibition in a local circuit that produces neural delays within the VNLL and therefore its output to the IC. The ramifications of this, and the reason that it occurs in only a subset of VNLL cells, are unknown but there are several J Neurophysiol • VOL possible outcomes at the IC. VNLL neurons receiving onset inhibition showed either a sustained or onset response to noise (Fig. 2b, 2 and 3, respectively). The response pattern of these VNLL neurons will determine the pattern of inhibition in the IC. Delayed inhibition from VNLL cells with a sustained response may create phasic responses in the IC (Fig. 2c1), while delayed inhibition from VNLL onset cells may mediate pauser IC responses (Fig. 2c2). The proposed VNLL circuitry predicts the presence of fast inhibition preceding excitation in the IC (Fig. 2d) because the inhibitory projection within the VNLL (Fig. 2, gray axon) is a collateral of an axon projecting to the IC. Note that the VNLL neuron (Fig. 2b) and the IC neuron (Fig. 2d) receive the same pattern of inputs, and therefore they would both be expected to exhibit similar onset inhibition. This prediction is supported by our intracellular recordings from IC neurons (Fig. 2d1) and previous reports (Adams 1997; Carney and Yin 1989; Kuwada et al. 1997; Smith et al. 1993). This inhibitory pathway to the IC is presumably broadly tuned and would provide a source of onset-evoked wideband inhibition to narrowly tuned IC neurons (Fig. 2d). In the ventral CN, a similar arrangement exists, 94 • AUGUST 2005 • www.jn.org Downloaded from jn.physiology.org on March 4, 2011 FIG. 2. Pathways mediating fast inhibition within the VNLL and IC. a: VNLL neuron receiving input from the octopus cell area (OCA) via a thick axon projection ending in a calyx. a1: intracellular response of a VNLL OI cell. b: VNLL neuron receiving onset inhibition via a collateral (gray) of an ascending axon. b1:VNLL cell with intermittent onset inhibition. Gray trace, response when inhibition was present; the black trace, response when it was absent. Inset: the average response (first 15 ms from stimulus onset) with (n ⫽ 3) and without (n ⫽ 7) inhibition. b, 2 and 3: overlayed traces (n ⫽ 20) of onset inhibition in 2 VNLL cells showing a sustained and onset response, respectively. c: an IC neuron receiving delayed inhibition from a VNLL cell with onset inhibition. c1: an IC neuron that receives delayed and sustained inhibition from a VNLL cell (as in b2) would be expected to exhibit a phasic response. c2: an IC neuron that receives delayed and onset inhibition from a VNLL cell (as in b3) would be expected to exhibit a pauser response. Inset: the average response (30 stimulus presentations; first 50 ms from stimulus onset). Pause in AP firing is between 11.7 and 19.4 ms. d: an IC neuron receiving input from a VNLL OI cell (as in a1) would be expected to show onset inhibition (d1) similar to that observed within the VNLL. Horizontal dashed lines indicate RMPs that were ⫺29, ⫺52, ⫺47, ⫺43, ⫺56, ⫺52, and ⫺26 mV for traces shown in a1, b1– b3, c1, c2, and d1, respectively. Traces shown in a1, b1, c1, c2, and d1 (excluding insets) are responses to a single stimulus presentation. In all cases, stimuli were 80 dB noise bursts. Inhibitory projections are shaded and excitatory projections are unshaded. Arrows indicate membrane hyperpolarization. All traces correspond with neurons in the circuit diagram with the equivalent letter. Report 1654 D.A.X. NAYAGAM, J. C. CLAREY, AND A. G. PAOLINI is mediated by glycinergic interneurons with onset responses, and results in the delay of the first AP to off-CF tones (Paolini et al. 2004). These descriptions of fast, onset inhibition at several levels of the auditory pathway suggest that it may be a widespread means of controlling first spike timing. ACKNOWLEDGMENTS We thank R. E. Millard for engineering support, A. Xipolitos for technical assistance, and Prof. G. M. Clark for mentoring and support. These experiments were conducted within the Department of Otolaryngology at The University of Melbourne. GRANTS This work was supported by a Dame Elisabeth Murdoch Scholarship to D.A.X. Nayagam administered by The Bionic Ear Institute. REFERENCES J Neurophysiol • VOL 94 • AUGUST 2005 • www.jn.org Downloaded from jn.physiology.org on March 4, 2011 Adams JC. Projections from octopus cells of the posteroventral cochlear nucleus to the ventral nucleus of the lateral lemniscus in cat and human. Audit Neurosci 3: 335–350, 1997. Awatramani GB, Turecek R, and Trussell LO. Inhibitory control at a synaptic relay. J Neurosci 24: 2643–2647, 2004. Batra R and Fitzpatrick DC. Discharge patterns of neurons in the ventral nucleus of the lateral lemniscus of the unanesthetized rabbit. J Neurophysiol 82: 1097–1113, 1999. Batra R and Fitzpatrick DC. 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